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IJSTR >> Volume 4 - Issue 7, July 2015 Edition

International Journal of Scientific & Technology Research  
International Journal of Scientific & Technology Research

Website: http://www.ijstr.org

ISSN 2277-8616

Elementary Particles: A New Approach

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ABSTRACT: It is shown the inexistence of neutrinos to define precisely the concept of relativistic’s mass; under this scheme, to elementary’s particles as electron and interaction’s particles like photons correspond an electromagnetic and virtual mass. Nucleons (protons and neutrons) have real or inertial mass for being composite particles, since inertia needs structure: it is provided by an interactive network originated by strong and weak forces. This mass is building up atoms and all the material world under Classical Physics and Chemistry’s laws.These actual masses may be considered as electromagnetic and virtual one (thanks to its charge), in order to establish the high energies level needed to obtain all particles physics (elementary or not), which are governed by the laws of Quantum Physics. With all this, one may set up amore reasonable and understandable new Standard Model, which being projected into Cosmological Model can get rid of some inconsistencies and concepts difficult to be admitted.



[1] Michi Kaku: Quantum Fiel Theory. Oxford Univers.Press (1993).

[2] Kaplan: Física Nuclear. Edit. Aguilar (1970).

[3] F.Wilzcek: Origins of mass. MIT (2012).

[4] G.Wick: Elementary Particles Physics. Pergamo Press (1971).

[5] Einstein: The principle of Relativity. Dover Publications. (1952).

[6] Einstein: El significado de la Relatividad. Espasa Calpe. (1984).

[7] Panofsky: Classical Electricity and Magnetism. Add. Wesley (1964).

[8] F.Mandl: Introduction Quantum Field Theory. Int. Science (1959).
[9] E. Segré: Núcleos y Partículas. Edit. Reverté (1972).

[10] Chris.Quigg: Spont.Symmetry Breaking as a basis of P.mass.CERN (2007).

[11] E.T.Jaynes: Scattering of light by free electrons. (1996).

[12] H.Muirhead: Elementary Particle Physics. Perg.Press (1971),

[13] P. Roman: Advanced Quantum Theory. Addison-Wesley (1965).

[14] A.Messiah: Mecánica Cuántica. Edit. Tecnos. (1962).
A. Sokolv: Electrodinamica cuántica. Edit. Mir. (1989).

[15] Ya-PeyChang: Gauge Theory Element.Particles. Oxford (1984).

[16] R.Mohapatra: Unification and Supersymmetry. Springer. (2203).

[17] M.Gabella: Non-abelian gauge symmet; gauge symmetry (2002).

[18] W.A. Tiller: Undert.Internal Symm: Gauge Symmetry (2002).

[19] Gerald’t Hooft: The universe of elementary particles. Utrecht (2002).

[20] The Feynman Lectures. Addison-Wesley (1965)

[21] Alonso-Finn: Fundamentos cuánticos y estadísticos: Aguilar Edic.(1971).

[22] D.Hestenes: Mysteries and insights of Dirac Theory. (2002).

[23] J. Bourjally: Non-abelian Gauge Invariance. Notes. (2004).

[24] C.Moller: The Theory of Relativity. Oxford University Press. (1972).

[25] H.Goldstein: Mecánica Clásica. Edic. Aguilar. (1963).

[26] Kittel: Elementary Statistical Physics. John Wiley. (1967).

[27] F.Smith-J.Thomson: Optics. John Wile and Sons. (1973).